Galvanically-isolated signaling between modules with step-up transformer

1. An integrated circuit configured for galvanically isolated signaling, the integrated circuit comprising an integrated circuit substrate manufactured to implement: a transfer conductor carrying a modulated carrier signal; a floating transfer loop electromagnetically coupled to the transfer conductor to receive the modulated carrier signal, wherein the floating transfer loop includes a primary of a step-up transformer; a receiver coupled to a secondary of the step-up transformer to receive the modulated carrier signal in an amplified, differential fashion, wherein the receiver demodulates the modulated carrier signal to obtain a digital receive signal; and an integrated resonator that mediates the electromagnetic coupling of the floating transfer loop to the transfer conductor, wherein the integrated resonator is a galvanically-isolated transfer loop resonant at a carrier frequency of the modulated carrier signal.

2. The integrated circuit of claim 1 , wherein the transfer conductor is laterally adjacent to the floating transfer loop.

3. The integrated circuit of claim 2 , wherein the transfer conductor electrically connects between bonding pads of the integrated circuit to form part of a galvanically-isolated transfer loop that connects the integrated circuit with another integrated circuit that provides the modulated carrier signal.

4. The integrated circuit of claim 1 , wherein the floating transfer loop includes a capacitor in series or parallel with the primary, making the floating transfer loop resonant at a carrier frequency of the modulated carrier signal.

5. The integrated circuit of claim 1 , wherein the receiver decodes oscillation pulses in the modulated carrier signal as transitions in the digital receive signal.

6. The integrated circuit of claim 5 , wherein upward and downward transitions are represented as oscillation pulses of different widths.

7. A multi-module integrated circuit that comprises a first module and a second module interconnected in an integrated circuit device package that includes: a transmitter in the first module, the transmitter configured to provide a modulated carrier signal; a receiver in the second module configured to demodulate the modulated carrier signal; and a galvanically isolated signaling path that conveys the modulated carrier signal from the transmitter to the receiver, wherein the signaling path includes: an inter-module floating transfer loop that includes a first transfer segment in the first module electrically connected to a second transfer segment in the second module, the first transfer segment electromagnetically coupled to the transmitter and the second transfer segment electromagnetically coupled to a second floating transfer loop that includes a primary of a step-up transformer; and a secondary of the step-up transformer coupled to the receiver.

8. The multi-module integrated circuit of claim 7 , further comprising an integrated resonator that mediates the electromagnetic coupling of the second transfer segment to the second floating transfer loop.

9. The multi-module integrated circuit of claim 8 , wherein the electromagnetic coupling mediated by the integrated resonator is provided by placement of the integrated resonator laterally adjacent to the second transfer segment.

10. The multi-module integrated circuit of claim 8 , further comprising a second integrated resonator that mediates the electromagnetic coupling of the first transfer segment to the transmitter, wherein each of the integrated resonators is a galvanically-isolated transfer loop resonant at a carrier frequency of the modulated carrier signal.

11. The multi-module integrated circuit of claim 10 , wherein the electromagnetic coupling mediated by the integrated resonator is provided by placement of the integrated resonator laterally adjacent to the second transfer segment, and wherein the electromagnetic coupling mediated by the second integrated resonator is provided by placement of the second integrated resonator laterally adjacent to the first transfer segment.

12. The multi-module integrated circuit of claim 7 , wherein the second floating transfer loop includes a capacitance in series or parallel with the primary, making the second floating transfer loop resonant at a carrier frequency of the modulated carrier signal.

13. A method of processing an integrated circuit substrate to implement an integrated circuit with at least one connection terminal for receiving galvanically isolated signaling, the method comprising: equipping the integrated circuit with a receiver of a modulated carrier signal, the receiver being connected to a secondary of a step-up transformer; connecting a transfer conductor to the connection terminal; and electromagnetically coupling the transfer conductor to a floating transfer loop that includes a primary of the step-up transformer, said electromagnetic coupling including: providing an integrated resonator laterally adjacent to the transfer conductor and laterally adjacent to the floating transfer loop, the integrated resonator being a galvanically-isolated transfer loop that is resonant at a carrier frequency of the modulated carrier signal.

14. The method of claim 13 , wherein said electromagnetic coupling includes positioning the transfer conductor laterally adjacent to the floating transfer loop.

15. The method of claim 14 , further comprising providing a capacitor in series or parallel to the primary to make the floating transfer loop resonant at a carrier frequency of the modulated carrier signal.

16. A method of processing an integrated circuit substrate to implement an integrated circuit with a first connection terminal for receiving galvanically isolated signaling, the method comprising: equipping the integrated circuit with a receiver of a modulated carrier signal, the receiver being connected to a secondary of a step-up transformer; connecting the first connection terminal to a second connection terminal with a transfer conductor; electromagnetically coupling the transfer conductor to a floating transfer loop that includes a primary of the step-up transformer; and forming an inter-module floating transfer loop by electrically connecting the first and second connection terminals to a remote pair of connection terminals which in turn are electrically connected by a remote transfer conductor.

17. The method of claim 16 , wherein each of said first and second connection terminals comprises a bonding pad on a first substrate, and wherein said remote pair of connection terminals comprises a pair of bonding pads on a second substrate.